EP0180712A1 - Process and apparatus for introducing acid slag-forming elements into a cupola furnace - Google Patents

Abstract

In a cupola furnace lining intended for long-term operation, the burn-off of silicon is reduced or a pick-up of silicon is effected by adding an acid slag former on the periphery of the furnace shaft.

Description

The invention relates to a working method for operating a cupola furnace, in particular a hot-wind cupola furnace, which is equipped with refractory equipment for a multi-day or multi-week operation, in which an acidic slag-forming additive is added.

The invention further relates to a device for operating a cupola furnace, in particular a hot-wind cupola furnace, which is equipped with the firest equipment for a multi-day or multi-week operation, with which an acidic slag-forming additive is added.

• - der Heißwind-Kupolofen, der mit einer täglich neu zugestellten sauren Stampfmasse ausgekleidet ist und bei dem die Winddüsen als Öffnung in der feuerfesten Ausmauerung ausgebildet sind. Dieser Kupolofen führt häufig zu einer unvollständigen Verbrennung des Kokses und zeichnet sich daher durch einen relativ hohen CO-Gehalt in dem Gichtgas aus. Die unvollständige Verbrennung wird durch die ungenügende Zufuhr von Verbrennungsluft in das Ofeninnere verursacht. Die in dem oberen Ofenschacht befindlichen metallischen Einsatzstoffe werden durch die reduzierende Atmosphäre im Ofenschacht verhältnismäßig wenig oxydiert. Da die Zone größter Hitze sich unmittelbar vor den Düsen befindet und die Düsen als Öffnungen in der feuerfesten Ausmauerung ausgebildet sind, wird das feuerfeste Material in der direkten Umgebung der Winddüsen besonders großer Hitze ausgesetzt. Das in der Nähe der Düsen befindliche feuerfeste Material wird außerdem durch die vom Koks und den Einsatzstoffen zurückprallenden Spritzer getroffen und unterliegt daher einem zusätzlichen Verschleiß.
  Das aus der Schmelzzone stammende, ausgewaschene feuerfeste Material und das von dem Herd stammende und dort durch Korrosion abgelöste weitere feuerfeste Material gelangt in die Schlacke. Bei einem Kupolofen für eine Schmelzleistung von 15 t/h kann die auf diese Weise an jedem Tag in die Schlacke kommende, im wesentlichen aus Kieselsäure bestehende feuerfeste Masse bis zu 4000 kg betragen.
• - der futterlose Heißwind-Kupolofen, der in seinem Herd mit einer kohlenstoff- und/oder tonerdehaltigen feuerfesten Auskleidung ausgerüstet ist und bei dem wassergekühlte Kupferdüsen eingesetzt werden, die in ihrer Anordnung und in ihrem Durchmesser so gewählt werden, daß eine wesentlich verbesserte Verbrennung des Gießereikokses in der Schmelzzone erreicht wird. Der futterlose Heißwind-Kupolofen kann daher, wenn dieses vom Betreiber gewünscht wird, mit geringeren Kokssätzen gefahren werden und hat dann im Oberofen eine geringer reduzierende Atmosphäre. Der futterlose Heißwind-Kupolofen hat im Bereich der Düsen und im Oberofen keine isolierende feuerfeste Auskleidung. Die Wärmeverluste durch den Ofenmantel sind beträchtlich.
  Ein Zufluß von saurer, im wesentlichen Kieselsäure enthaltender und aus der Düsenebene oder aus dem Bereich des Oberofens stammender feuerfester Masse in das Schlackenbad findet nicht statt. Wegen der hochwertigen Auskleidung des Herdes mit schwachsaurer oder neutraler, kohlenstoffhaltiger feuerfester Masse ist mit einem nennenswerten Zufluß eines sauren Schlackenbildners aus dem Bereich des Ofenherdes ebenfalls nicht zu rechnen.
• - der für Langzeitbetrieb vorgesehene gefutterte Heißwind-Kupolofen hat in dem Ofenherd eine kohlenstoff- und/oder tonerdehaltige feuerfeste Auskleidung und wassergekühlte Kupferdüsen, die in ihrer Anordnung und in ihrem Durchmesser so gewählt werden, daß eine vollständigere Verbrennung des Gießereikokses erreicht werden kann. Der Betreiber kann also, wenn er das wünscht, mit einer weniger reduzierenden Atmosphäre im Ofenschacht fahren. Die vor den Düsenköpfen liegende besonders heiße Zone im Schmelzbereich hat von der zurückliegenden feuerfesten Auskleidung einen solchen Abstand, daß der thermische Verschleiß des Futters in geringeren Grenzen bleibt und eine über mehrere Tage oder über mehrere Wochen ausgedehnte Ofenreise ermöglicht wird. Die gegenüber den in das Ofeninnere hineinragenden wassergekühlten Kupferdüsen zurückliegende feuerfeste Auskleidung wird auch weniger von den durch Einfluß des Windes zurückprallenden Schlackentröpfehen berührt, wodurch der chemisch-mechanische Angriff des Futters verringert wird.

The cupola furnace has been a well-known shaft furnace for a long time and is particularly used in foundries. It is used to melt liquid foundry pig iron from solid pig iron, steel scrap, broken cast iron and recycling materials from the foundry and works with coke as a fuel. The following three types of hot-wind cupola are mainly used:

• - The hot-wind cupola furnace, which is lined with a daily new acid pound compound and in which the wind vents are designed as an opening in the refractory lining. This cupola often leads to incomplete combustion of the coke and is therefore characterized by a relatively high CO content in the blast furnace gas. The incomplete combustion is caused by the insufficient supply of combustion air to the inside of the furnace. The metallic feedstocks located in the upper furnace shaft are comparatively little oxidized by the reducing atmosphere in the furnace shaft. Because the zone of greatest heat is just in front of the nozzles and the nozzles as openings in the fire solid brickwork are formed, the refractory material is exposed to particularly high heat in the direct vicinity of the wind vents. The refractory material in the vicinity of the nozzles is also hit by the splashes rebounding from the coke and the feed materials and is therefore subject to additional wear.
  The washed-out refractory material originating from the melting zone and the further refractory material originating from the hearth and detached there by corrosion end up in the slag. In the case of a cupola furnace with a melting capacity of 15 t / h, the refractory mass, which essentially consists of silica, and enters the slag every day can be up to 4000 kg.
• - The feedless hot wind cupola furnace, which is equipped in its hearth with a carbon and / or alumina refractory lining and in which water-cooled copper nozzles are used, which are chosen in their arrangement and in their diameter in such a way that a significantly improved combustion of the foundry coke is reached in the melting zone. The feedless hot-wind cupola furnace can therefore be operated with lower coke rates if the operator so desires and then has a lower reducing atmosphere in the upper furnace. The feedless hot-wind cupola furnace has no insulating refractory lining in the area of the nozzles and in the upper furnace. The heat losses through the furnace jacket are considerable.
  There is no inflow of acidic refractory material, which essentially contains silica and comes from the nozzle level or from the region of the upper furnace, into the slag bath. Because of the high-quality lining of the stove with weakly acidic or neutral, carbon-containing refractory mass, a noteworthy inflow of an acidic slag former from the area of the stove is also not to be expected.
• - the lined hot wind for long-term operation Kupolofen has a carbon and / or alumina refractory lining and water-cooled copper nozzles in the oven, which are chosen in their arrangement and in their diameter so that a more complete combustion of the foundry coke can be achieved. The operator can, if he so wishes, operate with a less reducing atmosphere in the furnace shaft. The particularly hot zone in front of the nozzle heads in the melting area has such a distance from the fireproof lining that the thermal wear on the feed remains within limited limits and enables an extended oven travel over several days or over several weeks. The refractory lining that lies behind the water-cooled copper nozzles that protrude into the furnace interior is also less affected by the slag droplets rebounding due to the influence of the wind, thereby reducing the chemical-mechanical attack of the feed.

The acidic slag formers coming from the area of the nozzles into the slag bath and resulting from the wear of the refractory lining have a much smaller quantity (200 kg daily) than in the short-term hot-wind cupola furnace lined first described (approx. 4000 kg daily).

• - mit wachsendem CO-Gehalt im Gichtgas,
• - mit wachsender Temperatur des Rinneneisens,
• - mit höherem Kieselsäureanteil in der Schlacke.

Silicon burn-off in a cupola furnace is reduced:

• - with increasing CO content in the blast furnace gas,
• - with increasing temperature of the gutter iron,
• - with a higher silica content in the slag.

The fed hot-wind cupola furnace with daily delivery has a relatively low silicon burn-off, because the combustion of the coke in the melting zone is bad due to the lack of wind nozzles and therefore the top gas contains a relatively high proportion of CO. The silicon burn-off is also low because a considerable amount of silica is added to the slag bath in the daily redelivery arrives so that the slag has no tendency to slag further silicon bound to the iron. The lined hot-wind cupola furnace with daily delivery therefore has advantages in terms of silicon erosion. On the other hand, it has disadvantages because it has a high coke consumption and because the daily delivery work has to be done.

The feedless hot wind cupola furnace has a relatively high silicon burn-off (e.g. 30%) because it has water-cooled copper nozzles and, if the nozzles are correctly designed, can run with more complete combustion, so that in this mode of operation there is a relatively low CO content in the blast furnace gas sets. Silicon erosion is also increased because the daily inflow of silica from the erosion of the feed is eliminated and therefore the slag has a greater tendency to slag the silicon bound to the iron. The feedless cupola furnace has an increased coke consumption because it has to cover the heat loss through the non-insulated water-cooled furnace jacket.

The lined hot-wind cupola furnace with refractory delivery for a multi-day or multi-week operation also has an increased silicon burn-off because it is equipped with water-cooled copper nozzles and can therefore be operated with more complete combustion of the coke in the melting zone and therefore often with a CO content in the blast furnace gas between 10 and 14% is driven. The lined hot-wind cupola with fireproof equipment for several days or weeks of operation also has an increased silicon burn-off, because the inflow of silica from the refractory material into the slag is low compared to the lined hot-wind cupola with daily delivery.

• - einen geringen Siliziumabbrand,
• - einen hohen Koksverbrauch,
• - einen hohen Aufwand für die feuerfeste Zustellung.

The lined hot-wind cupola with daily delivery therefore has:

• - low silicon burn-up,
• - high coke consumption,
• - a high cost for refractory delivery.

• - einen hohen Siliziumabbrand,
• - einen hohen Koksverbrauch,
• - einen niedrigen Aufwand für die feuerfeste Zustellung.

The feedless hot-wind cupola furnace therefore has:

• - high silicon erosion,
• - high coke consumption,
• - a low cost for refractory delivery.

• - einen hohen Siliziumabbrand,
• - einen niedrigen Koksverbrauch,
• - einen niedrigen Aufwand für die feuerfeste Zustellung.

The lined hot-wind cupola oven for delivery lasting several days or several weeks therefore has:

• - high silicon erosion,
• - low coke consumption,
• - a low cost for refractory delivery.

• - die künstliche Verstärkung der reduzierenden Atmosphäre im Oberofen durch Erhöhung des Koksssatzes,
• - die künstliche Erhöhung der reduzierenden Atmosphäre im Oberofen durch die Zugabe einer Kohle mit hohem Anteil flüssiger Bestandteile,
• - die Zugabe von Sauerstoff in die Winddüsen mit dem Ziel, die Eisenrinnentemperatur zu erhöhen,
• - die Zugabe von Kies oder Basalt oder anderer saurer Schlackenbildner in den Ofen, um den Anteil der Kieselsäure in der Schlacke zu erhöhen.

Many efforts have been made to reduce silicon erosion. Among others the following methods are known:

• - the artificial reinforcement of the reducing atmosphere in the upper furnace by increasing the coke rate,
• - the artificial increase in the reducing atmosphere in the upper furnace by adding coal with a high proportion of liquid components,
• the addition of oxygen to the wind vents with the aim of increasing the iron channel temperature,
• - The addition of gravel or basalt or other acidic slag formers in the furnace to increase the proportion of silica in the slag.

However, the methods described all have the disadvantage in common that the outlay is greater than the achievable benefit. By using one or more of the previously described methods, the goal of reducing the silicon erosion can be achieved. The desired macroeconomic advantage does not occur, or only partially.

A significant increase in the CO content in the blast furnace gas, which also results in a significant reduction in silicon burn-off, can only be achieved if the coke rate is increased by approx. 20 t. The additional cost for coke but are higher than the potential savings on silicon.

So in most cases the addition of gravel or basalt does not lead to an economic result,

because the addition of gravel over the cross-section leads to an increased slagging of the coke surface and therefore the desired carburization of the liquid iron can only be achieved by increasing the coke rate. In this case, too, the additional expense for coke is often not covered by the financial advantage that results from the reduction in silicon burnup.

The task is therefore to find a procedure with which the silicon burn-off can be reduced in cupola furnaces which are equipped for long-term operation.

The procedure underlying the invention for reducing the silicon erosion in hot-wind cupola furnaces with refractory equipment for continuous operation is to bring an acidic slag generator with one of the devices described in the invention to the periphery of the furnace interior in such a way that an inflow of silica into it Slag bath is formed without covering the entire surface of the coke with an acidic slag structure and making it more difficult to carburize the liquid iron. The process on which the invention is based then achieves the same inflow of an acidic slag-forming agent into the cupola furnace slag as with the devices described in the invention, as occurs in the fed hot-wind cupola furnace with daily delivery by burning off the acidic feed.

• - ein gefutterter Heißwind-Kupolofen mit täglicher Zustellung,
• - ein gefutterter Heißwind-Kupolofen mit feuerfester Zustellung für mehrtägigen oder mehrwöchigen Betrieb.

The procedure on which the invention is based is then shown quantitatively in an example. In the example, the slag formers are determined in kg / h, as is the case in cupola furnaces with a melt output of 10 t / h. In the calculation example, two furnaces are compared:

• - a lined hot-wind cupola with daily delivery,
• - A lined hot-wind cupola with fireproof delivery for operation lasting several days or weeks.

The second example can also apply to a feedless cupola furnace that is equipped for several weeks of operation.

• Schlackenbildner in kg/h bei 10 t/h Schmelzleistung
  • a) für den Ofen mit täglicher Zustellung:
    
  • b) für den Ofen mit zweiwöchentlicher Zustellung:
    

The numerical results are summarized in the table below:

• Slag generator in kg / h at 10 t / h melting capacity
  • a) for the oven with daily delivery:
    
  • b) for the oven with bi-weekly delivery:
    

The data compiled in the table refer to a coke rate of 10% and a limestone rate of approx. 33% of the coke rate. In addition, a silicon carrier in the form of FeSi briquettes or Sic briquettes would be added, which feeds slag formers into the furnace via its cement bond. For the calculation example, it was assumed that the silicon burn-off in the hot-wind cupola furnace fed with daily delivery is 15%, while the silicon burn-off for the furnaces with long-term feed is 30%.

The calculation example shows that the daily feed consumption represents a determining part of the daily slag balance. It is therefore more common practice to add the missing silica to the cupola in the form of gravel or basalt. However, this method does not lead to an economical result, especially in cupola furnaces that are operated with high steel scrap, because the addition of gravel over the entire furnace cross section leads to slagging of the coke surface and therefore, as already described, the required carburizing of the liquid iron can only be achieved can if the coke rate is increased significantly.

In a cupola furnace operated with 65% steel scrap, the coke rate must be increased from 9.5 to 11% in order to achieve the desired carburization down to a carbon content of 3.35% if the batch contains 15% gravel. of coke was added with the aim of reducing silicon burnup.

The process on which the invention is based avoids this disadvantage because the acidic slag-forming agent is added to the periphery of the cupola furnace and thus increases the silica content of the slag without preventing the coke surface from being washed off by the liquid lime produced by the reduction of limestone in the furnace within the melting zone.

The method on which the invention is based can be carried out in various ways. It is suggested that the gravel be distributed over the circumference of the loading bucket. Another suggestion is to add the gravel in the furnace head and, after adding a new batch, to distribute the gravel to the circumference of the furnace head. It is further suggested the gravel. into the ring-shaped suction chamber for the blast furnace gas. The gravel can roll here into a natural slope, which is created within the ring suction chamber for the top gas when the batch is added. Another proposal is to introduce foundry sand through the copper nozzles into the slag bath in such a way that the sand trickles down the periphery of the furnace and reaches the slag bath. Another method can be to introduce water-cooled lances into the furnace so that gravel can be added to the slag bath from above. Finally, the invention also relates to a process for introducing foundry sand laterally through the furnace hearth under the slag bath and distributing it as evenly as possible within the slag bath.

According to the invention, the devices provided for the introduction of silicon or sand are optionally also partially used to blow lime into the furnace in the form of quicklime, hydrated lime, limestone or sorption hydrate. The coke ash is to be liquefied more quickly by blowing in and the surface of the carbon particles is washed for contact with the liquid iron. The degree of carburization of the liquid iron depends on the contact between the liquid iron and the carbon coke. In this respect, the blowing in of lime can increase the degree of carburization overall and / or enable the use of coke with a higher ash content.

Another advantage of lime blowing is a reduction in the usual limestone use of the type. Limestone is a commonly used aggregate for coal stoves. Limestone is used because the slag produced in the cupola furnace usually outweighs the acidic components. The slag is created from the coke ash, the forage burnout, the burnout of the iron and its accompanying elements.

Components of the slag are silica, iron oxide and alumina, all acidic components. Lime as a basic additive is intended to neutralize the acidic slag. Limestone is always given for the genus because limestone is an extremely inexpensive raw material. In addition, limestone not only has a neutralizing effect on the acidic slag constituents, but also lime has a liquefying effect on the silica and alumina components. Lime also has a desulfurizing effect and has a favorable effect on dephosphorization and iron and manganese burn-up.

In an acid furnace, the usual limestone surcharge is between 15 and 40% of the coke rate. The limestone surcharge is not solely dependent on the coke rate. Rather, the limestone aggregate is adjusted according to the desired slag composition, especially taking into account the expected feed burnout.

In the basic furnace, some of the acidic slag produced is neutralized and liquefied by the feed band. However, lime is added to achieve a desired slag basicity (Ca0 / Si02) of 1.5 - 3.5. Since the strongly basic slags have a higher melting point, the liquefaction effect resulting from the addition of lime is often not sufficient, so that additional fluxing agents are added.

In terms of the type, the lime has a very large grain size and an unfavorable position. The individual lime particles are embedded between the other components of the genus. The lime particles naturally have an optimal effect on the neighboring coke particles, while the effect on distant coke particles is correspondingly low.

The blowing in of lime according to the invention has the advantage of small grain size and optimal distribution of the lime in the oven. The lime thus has much better reaction conditions than with the conventional use of limestone

Burnt lime has higher procurement costs than blow-in limestone. However, the use of quicklime can be significantly more economical. The cause lies in the necessary transformation of limestone (CaC0 ₃ ) into fired Ka1k (CaO). This transformation is caused by the reduction in the cupola furnace. This must be taken into account in the case of conventional limestone use within the scope of the class by means of an appropriately dimensioned coke set. In the case of quicklime, the forming process is not necessary. As a result, the coke rate can be reduced.

According to the invention, lime is ases in an amount of 10 -40% of the limestone set _e i _n g _ebl. The lime preferably has a dust form and is drawn off from a silo. In the silo, bridging is caused by striking and / or vibrating tools and / or by Prevents fluidization. The lime dust is removed via a dosing system. A screw conveyor and / or a cellular wheel sluice are suitable as dosing systems. The dosing system doses the lime dust into a compressed air stream from the ambient air drawn in or into a high-tension partial stream of the hot wind.

The lime dust is preferably carried into the wind form with the compressed air or the hot wind partial flow. The lime can also be metered into the ring line for the hot wind.

The lime mixes with the hot wind and is distributed in the oven by the hot wind and carried upwards. The washing process described above takes place.

• Fig. 1 einen Kupolofen mit Zugabe von Kies durch die Gasabzugskammer;
• Fig. 2 einen Kupolofen mit Einblasvorrichtung für Gießereineusand;
• Fig. 3 eine weitere Einblasvorrichtung für Gießereineusand an einem Kupolofen;
• Fig. 4 und 5 einen Kupolofen mit besonderem Begichtunpskübel;
• Fig. 6 eine Vorrichtung zum Einblasen von Kalkstaub.

The devices on which the invention is based are illustrated in the system and are described in detail below:

• 1 shows a cupola furnace with the addition of gravel through the gas discharge chamber;
• 2 shows a cupola furnace with a blowing device for foundry sand;
• 3 shows a further blowing device for foundry sand on a cupola furnace;
• Figures 4 and 5 a cupola furnace with a special Begichtunpskübel.
• Fig. 6 shows a device for blowing lime dust.

According to Fig. 1, a feedless or a cupola fed for long-term operation is provided. The cupola furnace has a filling shaft which projects into a gas discharge chamber 2 below. Under the gas extraction chamber 2, the cupola continues in a water-cooled shaft with a furnace wall 1 and a frame underneath. 1 is provided with water-cooled wind nozzles, not shown. The top gas line leading away from the gas discharge chamber 2 is designated by 6.

The gas discharge chamber 2 is fed with gravel via 4 lines 3. Two of the four lines 3 are shown in FIG. 1. The lines 3 open evenly distributed on the circumference of the gas discharge chamber 2 and in each case on the top of the chamber. The lines 3 start from a distribution chamber 7 and have such an inclination that the gravel given through the lines 3 can safely get into the gas discharge chamber.

The distributor chamber 7 is provided with a perforated floor. A line 3 is assigned to each hole. The opening width of the holes is essentially the same as the passage cross section of the lines 3.

The distributor chamber 7 is fed with a screw conveyor 4, which removes the gravel from a silo 5. If possible, the silo 5 is arranged at the level of the filling chute next to the filling chute, so that when the cupola furnace is filled with a measuring bucket, the filling bucket can also be used to fill the silo 5.

The screw conveyor 4 serves primarily as a metering device. It enables the gas discharge chamber 2 to be filled with gravel independently of the fill level of the silo 5. Furthermore, the screw conveyor 4 allows the flow of gravel to the gas discharge chamber 2 to be regulated.

The gravel entering the gas discharge chamber from four points from above is distributed evenly due to its free-flowing properties and penetrates into the cupola furnace in accordance with its bed height and the opening gap 8 in the cupola furnace wall. There, the gravel slides down the genus along the inner wall of the furnace without affecting the carburizing process in the inner region of the furnace. In addition, no impairment of the top gas discharge can be found.

As an alternative to the coating with lines 3, screw conveyor 4 and silo 5 provided according to FIG. 1, there is also an addition. of gravel in the filling shaft possible. According to the invention, this is done optionally with the aid of a dash-dotted chute 9 shown in FIG. 1. The chute 9 is arranged above the filling shaft and has an opening in the middle, the diameter of which is approximately equal to the inside diameter of the filling shaft. This opening allows the type given up from the top during the charging with the measuring bucket to pass into the filling shaft. At the same time gravel is placed on chute 9. The gravel slides on chute 9 into the filling shaft. By rotating chute 9 around the cupola The central axis of the furnace can also be ensured in the case of only one place for gravel on the chute that the gravel is distributed evenly over the circumference of the filling shaft. The gravel is removed from a silo as in the case of the use of the lines 3 and the screw conveyor 4.

• Statt der Klappen können die beiden ineinander angeordneten Trichter auch beweglich zueinander angeordnet sein. Dann bewirkt die gegeneinander gerichtete Bewegung der Trichter ein Verschließen des Innenraumes zwischen den Trichtern. Beim Auseinanderbewegen öffnet sich an der Unterseite der Trichter ein Spalt, durch den der Kies aus dem Innenraum austreten kann. Die Austrittsgeschwindigkeit läßt sich durch Einstellen eines entsprechend großen Spaltes der schnellen Entleerung der Begichtungskübel beim Begichten ^put anpassen.

Optionally, chute 9 itself forms the silo. The chute then consists, for example, of two funnels placed one inside the other, the interior of which is filled with gravel. The interior is the cavity between the two funnels and is closed by flaps, which either protrude into the fall path of the species abandoned from the tub and are then opened by the species; or the flaps are actuated via a lever mechanism that is activated together with the actuating elements for the inspection bucket (mostly levers for bottom flaps):

• Instead of the flaps, the two funnels arranged one inside the other can also be arranged to be movable relative to one another. Then the opposite movement of the funnels causes the interior between the funnels to close. When moving apart, a gap opens on the underside of the funnel through which the gravel can escape from the interior. The exit speed can be achieved by setting a suitably large gap the rapid emptying of the Begichtungskübel Begichten adjust ^p ut.

According to FIGS. 4 and 5, the gravel is placed in the method according to the invention with the aid of the surveying bucket. 4, the cupola has the designation 20, the cupola furnace the designation 21. When gravel was loaded with the surveying bucket 20 according to the invention, the gravel along the inner wall of the bucket was filled in together with the species in such a way that in the event of subsequent centralized loading (emptying of the flooring bucket) looking at me bucket of material is moved down essentially unchanged. In the filling shaft, the gravel then reaches the inside wall of the filling shaft, while the type remains in the center.

Central inspection can be carried out in this way by means of a steep elevator for extendable buckets, inclined elevators with automatic bucket insertion into the oven, monorail, crane or trolley inspection, and possibly a swivel arm.

According to Fig. 4, a loading with a crane trolley is provided. Fig. 4 shows the crane trolley 22 in different operating positions. The crane trolley 22 is movably arranged on a rail 23. In the drawing, the left operating position shows the raising or lowering of the leveling bucket. This process is initiated by actuating the pressure switch. The rest of the process is automatic. This means that after lifting the full coating bucket 20, it moves, carried by the crane trolley 22, over the filling shaft of the cupola furnace 21. When the emptying position has been reached, a limit switch is actuated which stops the crane trolley 22 and at the same time the crane trolley only loosely to catch up with it moving operating cables for the bottom flaps of the tub 20 causes. This causes the bottom flaps to open and the species to fall out of the inspection tub into the filling shaft of the cupola 21.

The crane trolley 22 then moves back to its starting position. This is achieved either by operating the operator or by timing relays which close the bottom flaps again and by limit switches which position the survey bucket 20 after stopping the crane trolley 22 and lowering the survey bucket 20 in the starting position.

According to FIG. 5, a sheet metal jacket 24 is placed in the coating bucket before the filling bucket 20 is filled again. This is done by means of the crane trolley 22. The sheet metal jacket has various eyes 25 which are evenly distributed around the circumference for hanging on hooks.

The sheet metal jacket 24 keeps an equal distance on all sides in the tub 20 from the inner walls of the tub. The distance corresponds to the thickness of the gravel layer provided on the inner walls of the surveying bucket 20. The gravel is optionally filled manually or using suitable filling devices into the space between the sheet metal jacket 24 and the inner walls of the surveying bucket 20. Simultaneously with the gravel, the genus can be filled into the interior of the sheet metal jacket 24. The genus can also be filled in before or after it has been filled with gravel.

When the coating bucket 20 is prepared with gravel and type, the sheet metal jacket 24 is pulled out again with the help of the crane trolley 22 and the next coating process can follow.

2, sand is used instead of gravel. The sand is blown into the cupola furnace designated 10 in FIG. The blowing takes place with a hot wind. For this purpose, the wind molds 11 are provided with a delivery line 12 which opens into a nozzle 13. The nozzle 13 ends under the nozzle mouthpiece 14 of the windform 11 in front of the furnace wall.

The sand is drawn off from a silo 16 via a screw 15 and / or cellular wheel sluice and metered continuously into the hot wind stream of the line 12. For this purpose, the screw 15 is arranged above the line 12. The sand then falls essentially without pressure into the hot wind stream of line 12. The pressure of the hot wind in line 12 is regulated by means of a valve.

The nozzle 13 blows the sand vertically down onto the slag. However, it is also possible to blow the sand below the bath level of the slag in the frame by extending the line 12 beyond the wind form 11. The line 12 then forms a lance and is expediently provided with water cooling on the part projecting beyond the windform 11. This water cooling can be combined with the water cooling of the windform 11.

According to FIG. 3, the sand is blown in via a lance 31 which projects past the wind forms 30 indicated by the broken lines. The frame of the cupola furnace is designated by 32 in FIG.

The lance 31 preferably opens in the region of a recess in the base of the frame.

In order to overcome the internal pressure of the cupola furnace without too much energy, the lance is connected to the hot wind ring 33 by a fan. As a result, the fan 34 only needs to bring the already pressurized wind, which acts as a carrier gas, to a somewhat higher pressure.

6 shows a device for blowing lime into the cupola furnace. This device differs essentially from the entry device according to FIG. 2 for sand in that the metering device designated by 22 is connected to the ring line. I.e. 6, an entry point on the ring line is sufficient to mix the lime dust with the hot wind. The metering device 22 then draws the lime dust out of a silo 21.

In special cases, however, a metering device can also be assigned to each wind form. This allows the flow of lime dust to be regulated in every type of wind.

Claims (14)

1. A process for melting pig iron in a cupola furnace with refractory equipment for a multi-day or multi-week operation with or without fire-proof insulation of the furnace shaft, characterized in that an acidic slag generator of the cupola furnace slag in the furnace of the furnace so to avoid silicon burnup or to support silicon firing is supplied that the carburization of the iron on the coke surface is not significantly hindered; 2. The method according to claim 1) characterized in that the acidic slag generator consists essentially of silica; 3. The method according to claim 1) characterized in that the acidic slag form consists of gravel or foundry sand; 4. The method according to claim 1) to 3) characterized in that the acidic slag generator is distributed over the circumference of the coating bucket and then remains predominantly on the circumference of the interior of the furnace until it gets into the furnace and the slag bath; 5. The method according to claim 1) to 3) characterized in that the acidic slag generator is added at several points on the circumference of the annular chamber for suctioning off the top gases and then remains predominantly on the periphery of the furnace interior until it gets into the furnace and there in the slag bath ; 6. The method according to claim 1) to 3) characterized in that the acidic slag generator from the water-cooled copper nozzles from the periphery of the furnace into the slag bath; 7. The method according to claim 1) to 3) characterized in that the acidic slag generator is added vertically or inclined to the slag bath; 8. The method according to claim 1) to 3) characterized in that the acidic slag generator is introduced directly into the slag bath; 9. The method according to claim 8) characterized in that the acidic slag generator is introduced below the slag level so that a good mixing of the slag generator is achieved with the slag already formed; 9 a. Method according to one or more of claims 1-9, characterized by the blowing in of lime. 9 b. Method according to claim 9 a, characterized in that the lime is blown in in the form of quicklime and / or limestone and / or hydrated lime and / or sorption hydrate. _{9 c} . Method according to claim 9 a or 9 b., Characterized in that the amounts of lime blown in replace 10-20% of the 40% of the limestone. 10. Apparatus for adding an acidic slag generator to a cupola furnace with a refractory equipment for a multi-day or multi-week operation with or without fireproof insulation of the furnace shaft, characterized in that the acidic slag generator z. B. is distributed in the form of gravel on the circumference of the bucket with the help of a rotating chute rotating about the bucket longitudinal axis and arranged above the bucket; 11. A device for a cupola furnace according to claim 10) characterized in that the acidic slag former z. B. is discharged in the form of gravel from one or more bunkers and is fed into the annular chamber for the extraction of the blast furnace gas by controlled distributors at several points around the circumference; 12. A device for a cupola furnace according to claim 10) characterized in that the acidic slag former z. B. in the form of foundry sand using a pneumatic blowing system through one or more wind vents along the wall of the furnace. is blown into the slag bath in a vertical direction; 13. A device for a cupola furnace according to claim 10) characterized in that the acidic slag former z. B. in the form of gravel through one or more water-cooled and protruding into the furnace downpipes directly into the slag bath; 14. Device for a cupola furnace according to claim 10) characterized in that the acidic slag former z. B. is blown in the form of foundry sand through one or more lances directly into the slag bath in the furnace and that the lance protrudes like a secant into the cross section of the furnace.

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